static void RADIO_HandleStateMachine(void) {
uint8_t status;
for(;;) { /* will break/return */
switch (RADIO_AppStatus) {
case RADIO_INITIAL_STATE:
RF1_StopRxTx(); /* will send/receive data later */
RADIO_AppStatus = RADIO_RECEIVER_ALWAYS_ON; /* turn receive on */
break; /* process switch again */
case RADIO_RECEIVER_ALWAYS_ON: /* turn receive on */
RX_POWERUP();
RF1_StartRxTx(); /* Listening for packets */
RADIO_AppStatus = RADIO_READY_FOR_TX_RX_DATA;
break; /* process switch again */
case RADIO_READY_FOR_TX_RX_DATA: /* we are ready to receive/send data data */
if (RADIO_isrFlag) { /* Rx interrupt? */
RADIO_isrFlag = FALSE; /* reset interrupt flag */
(void)CheckRx(); /* get message */
RADIO_AppStatus = RADIO_RECEIVER_ALWAYS_ON; /* continue listening */
break; /* process switch again */
}
if (CheckTx()==ERR_OK) { /* there was data and it has been sent */
RADIO_AppStatus = RADIO_WAITING_DATA_SENT;
break; /* process switch again */
}
return;
case RADIO_WAITING_DATA_SENT:
if (RADIO_isrFlag) { /* check if we have received an interrupt: this is either timeout or low level ack */
RADIO_isrFlag = FALSE; /* reset interrupt flag */
status = RF1_GetStatus();
if (status&RF1_STATUS_RX_DR) { /* data received interrupt */
RF1_ResetStatusIRQ(RF1_STATUS_RX_DR); /* clear bit */
}
if (status&RF1_STATUS_TX_DS) { /* data sent interrupt */
RF1_ResetStatusIRQ(RF1_STATUS_TX_DS); /* clear bit */
}
if (status&RF1_STATUS_MAX_RT) { /* retry timeout interrupt */
RF1_ResetStatusIRQ(RF1_STATUS_MAX_RT); /* clear bit */
RF1_Write(RF1_FLUSH_TX); /* flush old data */
RADIO_AppStatus = RADIO_TIMEOUT; /* timeout */
} else {
RADIO_AppStatus = RADIO_RECEIVER_ALWAYS_ON; /* turn receive on */
}
break; /* process switch again */
}
return;
case RADIO_TIMEOUT:
Err((unsigned char*)"ERR: Timeout\r\n");
RADIO_AppStatus = RADIO_RECEIVER_ALWAYS_ON; /* turn receive on */
break; /* process switch again */
default: /* should not happen! */
return;
} /* switch */
} /* for */
}
void nrf_simplebyte(uint8_t cmd) {
RF1_Write(cmd);
#if 0
cbi(PORTB, PIN_nCS);
spi_byte(cmd);
sbi(PORTB, PIN_nCS);
#endif
}
/* called to check if we have something in the RX queue. If so, we queue it */
static uint8_t CheckRx(void) {
uint8_t res = ERR_OK;
uint8_t RxDataBuffer[RPHY_BUFFER_SIZE];
uint8_t status;
RPHY_PacketDesc packet;
bool hasRxData;
hasRxData = FALSE;
packet.flags = RPHY_PACKET_FLAGS_NONE;
packet.phyData = &RxDataBuffer[0];
packet.phySize = sizeof(RxDataBuffer);
#if NRF24_DYNAMIC_PAYLOAD
packet.rxtx = RPHY_BUF_PAYLOAD_START(packet.phyData);
#else
packet.rxtx = &RPHY_BUF_SIZE(packet.phyData); /* we transmit the data size too */
#endif
status = RF1_GetStatus();
if (status&RF1_STATUS_RX_DR) { /* data received interrupt */
hasRxData = TRUE;
#if NRF24_DYNAMIC_PAYLOAD
uint8_t payloadSize;
(void)RF1_ReadNofRxPayload(&payloadSize);
if (payloadSize>32) { /* packet with error? */
RF1_Write(RF1_FLUSH_RX); /* flush old data */
return ERR_FAILED;
} else {
RF1_RxPayload(packet.rxtx, payloadSize); /* get payload: note that we transmit <size> as payload! */
RPHY_BUF_SIZE(packet.phyData) = payloadSize;
}
#else
RF1_RxPayload(packet.rxtx, RPHY_PAYLOAD_SIZE); /* get payload: note that we transmit <size> as payload! */
#endif
RF1_ResetStatusIRQ(RF1_STATUS_RX_DR|RF1_STATUS_TX_DS|RF1_STATUS_MAX_RT); /* make sure we reset all flags. Need to have the pipe number too */
}
if (status&RF1_STATUS_TX_DS) { /* data sent interrupt */
RF1_ResetStatusIRQ(RF1_STATUS_TX_DS); /* clear bit */
}
if (status&RF1_STATUS_MAX_RT) { /* retry timeout interrupt */
RF1_ResetStatusIRQ(RF1_STATUS_MAX_RT); /* clear bit */
}
if (hasRxData) {
/* put message into Rx queue */
res = RMSG_QueueRxMsg(packet.phyData, packet.phySize, RPHY_BUF_SIZE(packet.phyData), packet.flags);
if (res!=ERR_OK) {
if (res==ERR_OVERFLOW) {
Err((unsigned char*)"ERR: Rx queue overflow!\r\n");
} else {
Err((unsigned char*)"ERR: Rx Queue full?\r\n");
}
}
}
return res;
}
void APP_Run(void) {
static const uint8_t chRf[] = {2, 26,80};
static const uint8_t chLe[] = {37,38,39};
uint8_t i, L, ch = 0;
uint8_t buf[32];
nrf_cmd(0x20, 0x12); //on, no crc, int on RX/TX done
nrf_cmd(0x21, 0x00); //no auto-acknowledge
nrf_cmd(0x22, 0x00); //no RX
nrf_cmd(0x23, 0x02); //5-byte address
nrf_cmd(0x24, 0x00); //no auto-retransmit
nrf_cmd(0x26, 0x06); //1MBps at 0dBm
nrf_cmd(0x27, 0x3E); //clear various flags
nrf_cmd(0x3C, 0x00); //no dynamic payloads
nrf_cmd(0x3D, 0x00); //no features
nrf_cmd(0x31, 32); //always RX 32 bytes
nrf_cmd(0x22, 0x01); //RX on pipe 0
buf[0] = 0x30; //set addresses
buf[1] = swapbits(0x8E);
buf[2] = swapbits(0x89);
buf[3] = swapbits(0xBE);
buf[4] = swapbits(0xD6);
#if 0
nrf_manybytes(buf, 5);
#else
RF1_WriteRegisterData(RF1_TX_ADDR, &buf[1], 4);
#endif
buf[0] = 0x2A;
#if 0
nrf_manybytes(buf, 5);
#else
RF1_WriteRegisterData(RF1_RX_ADDR_P0, &buf[1], 4);
#endif
while(1) {
L = 0;
buf[L++] = 0x40; //PDU type, given address is random
buf[L++] = 11; //17 bytes of payload
buf[L++] = MY_MAC_0;
buf[L++] = MY_MAC_1;
buf[L++] = MY_MAC_2;
buf[L++] = MY_MAC_3;
buf[L++] = MY_MAC_4;
buf[L++] = MY_MAC_5;
buf[L++] = 2; //flags (LE-only, limited discovery mode)
buf[L++] = 0x01;
buf[L++] = 0x05;
buf[L++] = 7;
buf[L++] = 0x08;
buf[L++] = 'n';
buf[L++] = 'R';
buf[L++] = 'F';
buf[L++] = ' ';
buf[L++] = 'L';
buf[L++] = 'E';
buf[L++] = 0x55; //CRC start value: 0x555555
buf[L++] = 0x55;
buf[L++] = 0x55;
if(++ch == sizeof(chRf)) { /* channel hopping */
ch = 0;
}
//nrf_cmd(0x25, chRf[ch]);
(void)RF1_SetChannel(chRf[ch]);
//nrf_cmd(0x27, 0x6E); //clear flags
RF1_WriteRegister(RF1_STATUS, RF1_STATUS_RX_DR|RF1_STATUS_TX_DS|RF1_STATUS_RX_P_NO_RX_FIFO_EMPTY); /* clear flags */
btLePacketEncode(buf, L, chLe[ch]);
//nrf_simplebyte(0xE2); //Clear RX Fifo
RF1_Write(RF1_FLUSH_RX); /* flush old data */
//nrf_simplebyte(0xE1); //Clear TX Fifo
//RF1_Write(RF1_FLUSH_TX); /* flush old data */ /* done in RF1_TxPayload() */
RF1_TxPayload(buf, L);
#if 0
cbi(PORTB, PIN_nCS);
spi_byte(0xA0);
for(i = 0 ; i < L ; i++) {
spi_byte(buf[i]);
}
sbi(PORTB, PIN_nCS);
nrf_cmd(0x20, 0x12); //tx on
sbi(PORTB, PIN_CE); //do tx
delay_ms(10);
cbi(PORTB, PIN_CE); (in preparation of switching to RX quickly);
#endif
LED1_Neg();
WAIT1_Waitms(10);
} /* for */
}
